User Mobility Modeling and Characterization of Mobility Patterns Mahmood M. Zonoozi and Prem Dassanayake IEEE Journal on Selected Areas in Communications.

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Presentation transcript:

User Mobility Modeling and Characterization of Mobility Patterns Mahmood M. Zonoozi and Prem Dassanayake IEEE Journal on Selected Areas in Communications

Outline Introduction Tracing of A Mobile Inside The Cell Tracing of Mobile Outside The Cell Cell Residence Time Distribution Mean Cell Residence Time Effect of Change in Direction and Speed Average Number of Handovers Channel Holding Time Distribution Conclusions 2

Introduction The mobility model plays an important role in examining different issues involved in a cellular system such as handover, offered traffic, dimensioning of signaling network, user location updating, registration, paging, multilayer network management, and the like. 3

Introduction In the general case, the mobility modeling should include changes in both the direction and speed of the mobile. 4

Introduction The mobility model proposed in this paper considers all of the possible mobility-related parameters including: – Mobile origin attributes (initial position, direction, and speed) – Ongoing attributes (changes in position, direction, and speed) – Mobile destination attributes (final position, direction, and speed) 5

Introduction Another important parameter that appears in relation to cellular mobile systems is the channel holding (or occupancy) time. The channel holding time of a cell is defined as the time during which a new or handover call occupies a channel in the given cell, and it is dependent on the mobility of the user. 6

Outline Introduction Tracing of A Mobile Inside The Cell Tracing of Mobile Outside The Cell Cell Residence Time Distribution Mean Cell Residence Time Effect of Change in Direction and Speed Average Number of Handovers Channel Holding Time Distribution Conclusions 7

Tracing of A Mobile Inside The Cell 8

9

10

Tracing of A Mobile Inside The Cell 11

Tracing of A Mobile Inside The Cell 12

Tracing of A Mobile Inside The Cell 13

Outline Introduction Tracing of A Mobile Inside The Cell Tracing of Mobile Outside The Cell Cell Residence Time Distribution Mean Cell Residence Time Effect of Change in Direction and Speed Average Number of Handovers Channel Holding Time Distribution Conclusions 14

Tracing of Mobile Outside The Cell In order to follow the trajectory of a mobile moving outside a cell, it is necessary to trace it as it moves to adjacent cells, and this is described in [32]. [32] M. M. Zonoozi and P. Dassanayake, “A novel modeling technique for tracing mobile users in a cellular mobile communication system,” Int. J. Wireless Personal Commun., accepted for publication. 15

Outline Introduction Tracing of A Mobile Inside The Cell Tracing of Mobile Outside The Cell Cell Residence Time Distribution Mean Cell Residence Time Effect of Change in Direction and Speed Average Number of Handovers Channel Holding Time Distribution Conclusions 16

Cell Residence Time Distribution Depending on whether a call is originated in a cell or handed over from a neighboring cell, two different cell residence times can be specified. They are the new call cell residence time and the handover call cell residence time, respectively. 17

Cell Residence Time Distribution The new call cell residence time is defined as the length of time a mobile terminal resides in the cell where the call originated before crossing the cell boundary. 18

Cell Residence Time Distribution Similarly, the handover call cell residence time is defined as the time spent by a mobile in a given cell to which the call was handed over from a neighboring cell before crossing to another cell. 19

Cell Residence Time Distribution A computer simulation can be developed to study the mobility under generalized assumptions for different mobility-related parameters. – 1) Users are independent and uniformly distributed over the entire region – 2) Mobiles are allowed to move away from the starting point in any direction with equal probability 20

Cell Residence Time Distribution 21

Outline Introduction Tracing of A Mobile Inside The Cell Tracing of Mobile Outside The Cell Cell Residence Time Distribution Mean Cell Residence Time Effect of Change in Direction and Speed Average Number of Handovers Channel Holding Time Distribution Conclusions 22

Mean Cell Residence Time R is the cell radius and V is the speed of the mobile in the cell. 23

Outline Introduction Tracing of A Mobile Inside The Cell Tracing of Mobile Outside The Cell Cell Residence Time Distribution Mean Cell Residence Time Effect of Change in Direction and Speed Average Number of Handovers Channel Holding Time Distribution Conclusions 24

Channel Holding Time Distribution The channel holding (or occupancy) time is a random variable defined as the length of time starting from the instant a channel in a cell is seized by the arrival of either a new or a handover call, until the time the channel is released either by completion of the call or by handing over to another cell. 25

Outline Introduction Tracing of A Mobile Inside The Cell Tracing of Mobile Outside The Cell Cell Residence Time Distribution Mean Cell Residence Time Effect of Change in Direction and Speed Average Number of Handovers Channel Holding Time Distribution Conclusions 26

Conclusions Taking this excess cell radius into account for different values of drift and speed, a broad variety of cell coverage areas with different street orientations and traffic flows can be handled by the proposed mobility model. 27